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The Transcriptomic Blueprint of Molt in Rooster Using Various Tissues From Charton et al. BMC Genomics (2021) 22:594 https://doi.org/10.1186/s12864-021-07903-9 RESEARCH Open Access The transcriptomic blueprint of molt in rooster using various tissues from Ginkkoridak (Korean long-tailed chicken) Clémentine Charton1†, Dong-Jae Youm1†, Byung June Ko1, Donghyeok Seol1,2, Bongsang Kim1,2, Han-Ha Chai3, Dajeong Lim3 and Heebal Kim1,2* Abstract Background: Annual molt is a critical stage in the life cycle of birds. Although the most extensively documented aspects of molt are the renewing of plumage and the remodeling of the reproductive tract in laying hens, in chicken, molt deeply affects various tissues and physiological functions. However, with exception of the reproductive tract, the effect of molt on gene expression across the tissues known to be affected by molt has to date never been investigated. The present study aimed to decipher the transcriptomic effects of molt in Ginkkoridak, a Korean long-tailed chicken. Messenger RNA data available across 24 types of tissue samples (9 males) and a combination of mRNA and miRNA data on 10 males and 10 females blood were used. Results: The impact of molt on gene expression and gene transcript usage appeared to vary substantially across tissues types in terms of histological entities or physiological functions particularly related to nervous system. Blood was the tissue most affected by molt in terms of differentially expressed genes in both sexes, closely followed by meninges, bone marrow and heart. The effect of molt in blood appeared to differ between males and females, with a more than fivefold difference in the number of down-regulated genes between both sexes. The blueprint of molt in roosters appeared to be specific to tissues or group of tissues, with relatively few genes replicating extensively across tissues, excepted for the spliceosome genes (U1, U4) and the ribosomal proteins (RPL21, RPL23).By integrating miRNA and mRNA data, when chickens molt, potential roles of miRNA were discovered such as regulation of neurogenesis, regulation of immunity and development of various organs. Furthermore, reliable candidate biomarkers of molt were found, which are related to cell dynamics, nervous system or immunity, processes or functions that have been shown to be extensively modulated in response to molt. Conclusions: Our results provide a comprehensive description at the scale of the whole organism deciphering the effects of molt on the transcriptome in chicken. Also, the conclusion of this study can be used as a valuable resource in transcriptome analyses of chicken in the future and provide new insights related to molt. Keywords: RNA-Seq, Molt, Transcriptomics, Micro RNA, Differential gene expression, Differential transcript usage * Correspondence: [email protected] †Clémentine Charton and Dong-Jae Youm contributed equally to this work and share the first authorship. 1Department of Agricultural Biotechnology and Research Institute of Agriculture and Life Sciences, Seoul National University, Seoul, Republic of Korea 2eGnome, Inc, Seoul, Republic of Korea Full list of author information is available at the end of the article © The Author(s). 2021 Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/. The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated in a credit line to the data. Charton et al. BMC Genomics (2021) 22:594 Page 2 of 24 Background If the impact of molt on the organism has to date Molt is a physiological event existing in multiple phyla been poorly investigated in comparison to other across the animal kingdom, characterized by a periodic physiological events, so have been its control and partial or complete shedding and replacement of the or- mechanisms. In many avian species, circadian and cir- ganism’s outer layer. In birds and mammals, molt is as- cannual rhythms are under the influence of the sociated to a variable loss and replacement of worn photoperiod. These rhythms, mediated by the neural appendages (feathers or hair). In birds, molt is a critical and endocrine systems, regulate essential physiological stage in the life cycle as individual fitness tightly depends processessuchasreproduction[7, 8]. Molt occurs on the functionality of its plumage, which, besides flight, naturally in birds at the end of the breeding period. also regulates thermoregulation and mating aptitudes. In domesticated chicken, though molt can be artifi- Despite its crucial influence on the organism, molt re- cially induced by dietary modifications (starvation, di- mains one of the most poorly understood and studied ets deficient or unbalanced in an essential nutrient physiological event [1]. such as calcium or zinc), postnuptial molt is naturally Renewing of plumage could be considered as the ‘tip induced by photoperiod [4]. In the jungle fowl of the iceberg’ when describing the physiological changes (Gallus gallus), wild progenitor of the domesticated occurring during molt in birds. If feather loss is un- chicken, molt is initiated during broodiness [7, 9]. Ac- doubtedly the most remarkable manifestation of molt, cordingly, natural molt is regulated by a variety of this process deeply affects a much wider range of tissues. hormones whose synthesis and secretion is influenced Increase in metabolic rate, remodeling of the reproduct- by seasonal effects acting on the pituitary gland ive tract, transient modification of the immune system, (mainly through melatonin signaling and hypothal- osteoporosis, modification of proteins synthesis, decrease amic control) [8]. Reproductive hormones such as in body fat and increase vascularization in the dermis oestrogen and testosterone have been shown to in- are all documented consequences of molt, reviewed by hibit the onset of molt whereas prolactin and the thy- Kuenzel et al. 2003 [2]. The decrease or quiescence of roid hormone thyroxine have been proved to be the reproductive function certainly has been the most exten- most effective hormones in inducing molt [2]. Prolac- sively depicted physiological effect of molt because of its tin, whose concentration rise as the reproductive cycle economic impact. Indeed, in commercial laying hens, proceeds, inhibits the hypothalamic-pituitary-gonadal the diminution or even cessation of eggs production oc- axis, and particularly the secretion of gonadotropin curring during molt impacts the overall profitability of releasing hormone (GnRH) and luteinizing hormone the flock. More specifically, molt triggers a regression (LH). This rise in prolactin concentration closely and remodeling of the ovaries and oviducts in hens. The matches the onset of broodiness, followed by the in- tubular glands, the structure at the origin of the forma- activation of the reproductive function [7]. By con- tion of the double-layered shell membrane of eggs, has trast, thyroxine is suspected to be the main been shown to degenerate and reform during molt, responsible for the onset of feather loss and replace- probably by a combination of apoptosis, autophagy and ment by increasing metabolic activity of feather folli- necrosis [3, 4]. Similarly, ovarian stroma has been shown cles, in a permissive rather than causal manner [8]. to undergo a regression followed by further recrudes- Thyroxine however does not seem to exert an influ- cence [4]. Though less documented, molt appears to im- ence on reproduction, so that feather loss and repro- pact the immune system in a contrasted way/manner. ductive cycle might be under separate control [7]. On one hand, in chicken, reproductive quiescence has While prolactin and thyroxine seem to be the hor- been shown to be associated with recrudescence and mones most intimately related to molt, a variety of lymphotic repopulation of the thymus, and, as such, other hormones interact to regulate molt: increased might promote immune function [5]. On the other hand, cortisol levels has for example been found to suppress a transient decrease in the number of B cell has been thyroid hormones, resulting in slower and longer molt shown in fasting-induced molts and might contribute in [8]. Cortisol and oestrogen have also been reported to reducing immune function in response to new antigenic suppress feather synthesis, in opposition to thyroxine challenges [6]. As all the physiological changes associ- and progesterone which promotes it [8]. ated with molt described in the above indicate a state of Despite the potential insights that could arise from stress, it has been proposed that molt could be associ- deciphering such an extensive tissue remodeling event, ated to a shift in the balance of the autonomic nervous to date, only one study investigated molt on the gene ex- system. More precisely, molt could correspond to a pression level and focused on laying hens’ reproductive change of dominance from the parasympathetic nervous tract alone [4]. This present study was designed as the system (activated during reproduction) in the direction first big scale transcriptomics analysis of molt in of the sympathetic system [2]. chicken. Messenger RNA sequencing was performed Charton et al. BMC Genomics (2021) 22:594 Page 3 of 24 across a total of 24 tissues issued from nine male Gink- encompassing blood, tissues from the nervous, repro- koridak individuals, and blood was collected on twenty ductive and the digestive systems and from the skin.
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